Reversible covalent chemistry of carbon dioxide unlocks the recalcitrance of cellulose for its enzymatic saccharification

Gan, Jianyun; Peng, Xinwen; Chen, Qin; Hu, Gang; Xu, Qin; Jin, Longming; Xie, Haibo

doi:10.1016/j.biortech.2019.122230

Cited by 14 publications

(2 citation statements)

References 47 publications

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“…The results showed a maximum conversion of cellulose to glucose of up to 95.6%. Li et al [158] and Gan and Peng [159] concluded with similar results using cellulose as feedstock. Moreover, MCW could be separated from mixed MW and gathered with the rest of lignocellulosic MW (textiles, paper, etc.)…”

Section: Energy Fuels and Materials Produced By Medical Waste Treatmentmentioning

confidence: 52%

Medical Waste Treatment Technologies for Energy, Fuels, and Materials Production: A Review

2021

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The importance of medical waste management has grown during the COVID-19 pandemic because of the increase in medical waste quantity and the significant dangers of these highly infected wastes for human health and the environment. This innovative review focuses on the possibility of materials, gas/liquid/solid fuels, thermal energy, and electric power production from medical waste fractions. Appropriate and promising treatment/disposal technologies, such as (i) acid hydrolysis, (ii) acid/enzymatic hydrolysis, (iii) anaerobic digestion, (vi) autoclaving, (v) enzymatic oxidation, (vi) hydrothermal carbonization/treatment, (vii) incineration/steam heat recovery system, (viii) pyrolysis/Rankine cycle, (ix) rotary kiln treatment, (x) microwave/steam sterilization, (xi) plasma gasification/melting, (xii) sulfonation, (xiii) batch reactor thermal cracking, and (xiv) torrefaction, were investigated. The medical waste generation data were collected according to numerous researchers from various countries, and divided into gross medical waste and hazardous medical waste. Moreover, the medical wastes were separated into categories and types according to the international literature and the medical waste fractions’ percentages were estimated. The capability of the examined medical waste treatment technologies to produce energy, fuels, and materials, and eliminate the medical waste management problem, was very promising with regard to the near future.

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Section: Energy Fuels and Materials Produced By Medical Waste Treatmentmentioning

confidence: 52%

Medical Waste Treatment Technologies for Energy, Fuels, and Materials Production: A Review

2021

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“…For this reason, polymorphic changes in cellulose can determine its derivatization. For example, Gan et al (2020) reported tetramethyl guanidine-assisted catalysis for the polymorphic conversion of I to II of cellulose under a carbon dioxide (CO2) atmosphere at 50 °C using DMSO as a solvent, thus…”

Section: Oeps From Cellulosementioning

confidence: 99%

Organocatalytic esterification of polysaccharides for food applications: A review

Ragavan

Hernández‐Hernández

Martínez

et al. 2022

Trends in Food Science & Technology

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Enhanced dissolution of cellulose in CO2 switchable system by solvent with low Henry's constants as CO2 absorbent

Zhang

Liu

et al. 2022

Cellulose

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Reversible covalent chemistry of carbon dioxide unlocks the recalcitrance of cellulose for its enzymatic saccharification

Cited by 14 publications

References 47 publications

Medical Waste Treatment Technologies for Energy, Fuels, and Materials Production: A Review

Medical Waste Treatment Technologies for Energy, Fuels, and Materials Production: A Review

Organocatalytic esterification of polysaccharides for food applications: A review

Enhanced dissolution of cellulose in CO2 switchable system by solvent with low Henry's constants as CO2 absorbent

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